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Privacy Policy Bei der Zusendung Ihrer Bewerbungsunterlagen werden Ihre Bewerber- und Bewerbungsdaten von uns zur Abwicklung des Bewerbungsverfahrens elektronisch erhoben und verarbeitet. Rechtsgrundlage für diese Verarbeitung ist § 26 Abs. 1 S. 1 BDSG i.V.m. Art. 88 Abs. 1 DSGVO. Sofern nach dem Bewerbungsverfahren ein Arbeitsvertrag geschlossen wird, speichern wir Ihre bei der Bewerbung übermittelten Daten in Ihrer Personalakte zum Zwecke des üblichen Organisations- und Verwaltungsprozesses – dies natürlich unter Beachtung der weitergehenden rechtlichen Verpflichtungen. Rechtsgrundlage für diese Verarbeitung ist ebenfalls § 26 Abs. 1 S. 1 BDSG i.V.m. Art. 88 Abs. 1 DSGVO. Bei der Zurückweisung einer Bewerbung löschen wir die uns übermittelten Daten automatisch drei Monate nach der Bekanntgabe der Zurückweisung. Rechtsgrundlage ist in diesem Fall Art. 6 Abs. 1 lit. f) DSGVO und § 24 Abs. 1 Nr. 2 BDSG. Unser berechtigtes Interesse liegt in der Rechtsverteidigung bzw. -durchsetzung. Sofern Sie ausdrücklich in eine längere Speicherung Ihrer Daten einwilligen, bspw. für Ihre Aufnahme in eine Bewerber- oder Interessentendatenbank, werden die Daten aufgrund Ihrer Einwilligung weiterverarbeitet. Rechtsgrundlage ist dann Art. 6 Abs. 1 lit. a) DSGVO. Ihre Einwilligung können Sie aber natürlich jederzeit nach Art. 7 Abs. 3 DSGVO durch Erklärung uns gegenüber mit Wirkung für die Zukunft widerrufen.

FAQ - Frequently Asked Questions I would like a VINCENT prosthesis. What do I need to do? You can get an appointment for a consultation and a prosthetic fitting from an orthopedic technician who has experience in the field of arm prosthetics. For a consultation appointment and fitting of a VINCENT prosthesis, the prosthetist must have attended appropriate training and obtained a certificate for these products. You can find a list of certified partners here: Partners near you . Does health insurance pay for the prosthesis? The costs for a prosthetic fitting with a VINCENT hand system are usually covered by all insurance providers. However, it is always an individual decision by the respective health insurance company whether a fitting is approved in each case. This depends on many factors that affect the prosthesis user, not so much the hand prosthesis. As soon as a prescription from the doctor is available, the prosthetist applies to the health insurance company for the fitting. If the application is rejected, this preliminary decision can also be appealed, and the prosthetist will usually handle this for you as well. An experienced prosthetist knows the legal situation; he can advise you and guide you through the process to the finished prosthesis. From what age is the VINCENTyoung3+ suitable? We recommend our pediatric and adolescent hand prosthesis from the age of 8. Ultimately, it depends on the development of the child. Let our certified partners advise you. Can I get my prosthesis wet? All VINCENT prostheses are splash-proof. The Evolution3+ and the Evolution4 are water resistant, these hands can be cleaned under running water and immersed in water, the immersion depth is not limited by the hand but by the water protection of the prosthesis stem. The Evolution4 has the highest water protection in the range of multi-articulating hand systems. Can I drive when wearing a prosthesis? Please do not drive in road traffic with your VINCENT prosthesis without further notice and observe our safety and warranty information. In order to be allowed to drive a vehicle with a hand prosthesis, a corresponding modification as well as the approval of the registration authority / TÜV [German technical inspection association] is usually required. Please contact your local registration office for more information. Do I have to wear a glove with the VINCENT prostheses? The hand has been designed to follow an aesthetic and anatomical shape even without a cosmetic glove . Materials and passive elasticities in the joints convey a natural feel. Therefore, most users wear the hand without a cosmetic cover. Vincent’s artificial hand systems combine excellent high-tech with design and quality. They are like a piece of clothing that underlines the personality of its wearer. Most people find the technology fascinating, combined with a positive interest in the new type of artificial hand. What should I do if the prosthesis breaks? Should it ever happen that the prosthesis no longer works, the orthopedic technician is the first port of call. He will take care of the repair or may even be able to solve the problem. How loud is the prosthesis? Depending on the prosthesis variant , there are up to 6 motors in an artificial hand. These rotate at a high speed and drive the prosthesis via a multi-stage planetary gear and another gear stage directly in the finger joint. This causes a motor noise depending on the muscle signal-controlled speed. The noise becomes louder the more motors run simultaneously and the faster they rotate. Slow hand movements are therefore also very quiet, comparable, for example, to the noise of an electric telephoto lens of a digital camera. The hand is loudest when all motors are closed simultaneously at maximum speed, e.g. in the cylinder grip. This noise can then be compared to the moving noise of a model railroad, for example. The user of the hand can therefore control the soundscape very easily via his muscle signals. How heavy is the hand? A natural human hand of an adult weighs about 350 g to 500 g, depending on body size. The weight of an artificial hand is not distributed as optimally on the arm as that of the natural one. Also, the weight of the socket, liner and the battery add to the weight of the prosthesis. In addition, the heaviest component of the prosthesis, the hand, is located at the outermost, distal end of the arm, so the leverage ratios are particularly unfavorable. A hand prosthesis must therefore be as light as possible. VINCENT hand systems weigh between approx. 300 g and 480 g, depending on the type of hand. Do you have further questions?

History of the Fluidhand and the VINCENTevolution 1998 Fluidhand 1 thin foil soft robot hand with 5DOF, 5iDOF This first soft hand consists of thin foil layers, which have been joined together to form more complex drives in a sandwich construction. Five fingers, built up from 6 foil layers each, functionally welded in pairs, with the middle two foils forming the skeletal structure filled with epoxy resin. The outer two foil layers each form a fluidic muscle. For this purpose, two thin films were welded together in such a manner that chambers were formed in a row and connected to each other. When this structure is inflated with a gas or liquid, it contracts by about 20% of its length, similar to the natural muscle, and the finger curls up like a bow. Read more 1999 Fluidhand 2 silicon tube soft sobot hand with 16DOF, 11iDOF The new planar technology for manufacturing fluidic drives and kinematics was therefore ideally suited for actively moving miniature catheters and endoscopes. However, the forces achievable with planar film drives, which operate at a working pressure of 0.5-1 bar, were too low for the construction of an artificial hand. To generate higher grasping forces, a correspondingly higher working pressure had to act in the fluidic drives. For Fluidhand 2, “artificial muscles” based on thin silicone hoses were therefore used, which were sheathed with a flexurally flexible, stretch-resistant fabric made of polyamide. Read more 2000 Fluidhand 3 rubber bulg soft hand prosthesis with 10DOF, 1iDOF With the third generation of the Fluidhand, Schulz transferred the technology of flexible fluid actuators to a hand prosthesis. To achieve higher grasping forces, the drives were modified for grasping even heavy objects. The unfolded silicone tubes reinforced with fabric were replaced by miniature folded bellows, which in turn were encased in fabric and attached to aluminum joints in the folds by nylon threads to keep their shape. Three drive elements in each finger, with the two distal bellows coupled together, and two drives in the thumb allow 14 joint axes to move in this hand, equivalent to 14 DOF at 10 iDOF. The fluid actuators were driven by means of miniature hydraulics. The control system, consisting of pump, valve, electronics, sensors and tank, was connected to the prosthesis via a hose approximately 1 m long. The hydraulic unit was the size of a portable telephone and was worn on the belt. Read more 2001 Fluidhand 4 rubber bulg soft hand prosthesis with 10DOF, 6iDOF The Fluidhand 4 has 10 flexible bellows drives, each of which, when pressurized, angles an aluminum joint by 90 degrees. Stretching is achieved by suction of the drive medium and by additional elastic bands. Each long finger has two drives that are fluidically coupled to each other and each leads to a common control valve in the metacarpus. The thumb has two individually movable drives, each of which is actuated by a separate valve. The drive medium is water. This hand prosthesis operates hydraulically for the first time. A miniature pump draws the fluid from an elastic reservoir in the forearm and pumps it at up to 6 bar via the valve bank into the bellows drive chambers. The pump and valves are controlled by a microprocessor in the hand, and the prosthesis wearer gives the control commands via myoelectric sensors. Read more 2002 Fluidhand 5 rubber bulg soft handprosthesis with 8DOF, 5iDOF The Fluidhand 5 was designed with the aim of integrating all system components of miniature hydraulics into the metacarpals in order to make the hand compatible with established socket systems. The prosthesis can be connected to all standard prosthetic sockets via a quicksnap wrist. Both the myoelectric sensors and the energy storage of the socket are used. The pump, fluid tank, valve bank and controller are located in and on the metacarpus. With the reduction in tank size, the number of fluidic drive was reduced to 8. The ring finger and little finger are flexed over one drive each. In the weight-optimized frame in sandwich construction, the elastic finger abduction was integrated. Five valves control the 8 drives of the hand, with the ring, little and middle fingers being hydraulically connected to each other. Read more 2003 Fluidhand 6 rubber bulg soft handprosthesis with 4DOF, 3iDOF The Fluidhand 6 is a particularly compact version of the hydraulic hand prosthesis, reduced to the essentials. The index, middle and ring fingers are each moved in the base joint via a flexible bellows drive, the little finger is mechanically coupled to the ring finger, and the middle finger is hydraulically coupled to the ring finger. The thumb is actuated in the basic joint. In this way, the thumb and index finger can be moved separately, while the other fingers move together. The 4 drives are controlled by a 3 valve bank, the miniature pump sucks distilled water from a pressure storage tank to pump it into the drive chambers. The weight of the hand is about 350 g. The aluminum fingers were covered with a PU foam. In the basic joints, all long fingers have an elastically mounted abduction. Weiter lesen 2004 Fluidhand 7 rubber bulg soft handprosthesis with 8DOF, 8iDOF The Fluidhand 7 is designed as an experimental hand. It is used to develop new control methods and to test a new tank system that is capable of storing energy. The hand therefore has one valve for each of the 8 drives. A type of spring accumulator was developed for the hydraulic tank, which allows the hand to be closed quickly and silently without the hydraulic pump operating. Due to the large number of new and experimental components, the metacarpus has turned out to be significantly larger than the previous model, but at this stage of development, the anatomical shape and size of the hand is not a priority. Read more 2005 Fluidhand 8 rubber bulg soft handprosthesis with 8DOF, 4iDOF The Fluidhand 8 has 8 drives that are controlled via 5 valves. The bellows in the index finger and middle finger are each hydraulically coupled with each other, and the drives of the ring and little fingers are also connected with each other via a common valve. The special feature of this further development is that the metacarpus has been replaced by a hermetically sealed pressure body. Inside the metacarpus is an elastic tank in the form of a diaphragm, in which both the drive medium (vegetable oil) and the control electronics, valves and pump are integrated; all system components "float" permanently in the drive medium. Between the pressure body shell and the diaphragm there is again a two-phase gas with a constant pressure of 2 bar. Read more 2006 Fluidhand 9 rubber bulg soft handprosthesis with 5DOF, 5iDOF The Fluidhand 9 has 5 drives of different sizes. The base joints of the index finger and middle finger are equipped with stronger drives. The elastic fluid tank is located in the wrist. When the fingers are emptied, they are stretched and the fluid is pumped from the finger joints into the elastic tank in the wrist, bending the wrist and opening the hand further. The pump is noise-isolated and free-swinging in a CFRP tank; valves and controls are located in the metacarpus, which is completely covered with CFRP. The thumb with a drive in the base pivots between flat hand and opposition position to the three-point grip. Read more Current products

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VINCENTwork The VINCENTwork prosthesis system is an orthopedic aid for everyday work but also for competitive athletes. In particular, training with heavy weights is an important training discipline in numerous sports. Previous fittings in the field of prosthetics were not designed for the high loads involved in competitive sports. The new prosthesis series makes it possible to train with weights of up to 200 kg. Snatching and alternating loads are also permitted without any problems at the maximum weights. A special feature is the flexible wrist. This allows a movement compensation between the training weight and the forearm stem. The joint flexes in all directions in a damped manner and also allows unlimited rotation compensation. Shocks and tensile forces are elastically absorbed and damped. The concept allows improved, symmetrical training with both arms and thus supports a natural movement pattern. This not only makes training more efficient, but also less stressful for the joints and the entire musculoskeletal system. Equipped with a shock-absorbing, rotating and angle-compensating wrist, the sports prosthesis enables safe training without limits. Flyer VINCENTwork

Textile gloves & Accessories - GF glove factory GmbH GF. COSMETIC GLOVE - Cosmetic gloves GF. COLOR GLOVE - Unicolor gloves GF. THERMO SLEEVE - Textile sleeve for the prosthetic socket GF. WORK GLOVE - Work gloves GF glove factory GmbH GF. cosmetic gloves GF. color gloves

Seit nun mittlerweile über 10 Jahren steht die Marke Vincent Systems für hochklassige qualitative Handprothesen, die stetig unter dem Aspekt weiterentwickelt werden und hierfür bereits mehrfach ausgezeichnet wurde. Awards

Patents All our products are registered and protected by the following United States patents: US8491666: VINCENTevolution1, VINCENTevolution3, VINCENTevolution3+, VINCENTevolution4, VINCENTevolution5, VINCENTpartial3, VINCENTpartial3+, VINCENTpartial4, VINCENTyoung3, VINCENTyoung3+ US9072616: VINCENTevolution2, VINCENTpartial2, VINCENTyoung2 US11517454 and by the following German and European patents: DE102014011554, DE102017005765, DE102016014090, DE102017010840, DE102017007794, DE102008056520, DE202014003565, DE202017000172, DE102017005761, DE102017005762, DE102017005764, DE102012005041, EP2364129 and others.

Close Up VINCENTmobile App TRAINING The grasping scheme is illustrated here. Additionally, the grasp the prosthesis is currently in as well as an animation of how the prosthesis fingers are supposed to move is displayed here. Here you can train the numerous grasps of the VINCENT hand prostheses. Up

neo1 - World's first under-clothing myoelectric exoskeleton for the upper extremity With neo1, Vincent Systems presents the breakthrough myoelectric exoskeleton designed specifically for users with limited upper extremity functionality, especially to compensate for paralysis caused by stroke and plexus injuries. This innovative technology uses advanced myoelectric control in conjunction with powerful micromotors in the elbow and hand areas to help users with their mobility and independence challenges due to their limitations. The myoelectric exoskeleton uses state-of-the-art sensor technology that detects and interprets the electrical signals generated by the user's muscles. By analyzing these signals, the exoskeleton intuitively responds to the user's movement intentions and allows them to regain control over their affected limbs. One of the most important features of this exoskeleton is its lightweight and ergonomic design. It is the world's first actively controlled exoskeleton that can be worn under the user's clothing due to its slim shape that is adapted to the body. This feature opens up a whole new horizon of applications as the system can be inconspicuously integrated into everyday life. Vincent Systems emphasizes comfort and adaptability, allowing users to wear the device for extended periods of time. The exoskeleton is customized to fit each user's anatomy. The control system is also user-specific, optimally adjusted for each wearer through a variety of parameters depending on the severity of the paralysis and the available muscle signals. In addition, the myoelectric exoskeleton offers different levels of support, allowing the user to gradually increase muscle activation and improve strength and control over time. This progressive approach promotes neuroplasticity and thereby also supports active rehabilitation. In the long term, positive effects are expected with regard to the reduction of phantom limb pain as well as a preventive effect with regard to the avoidance of overuse symptoms. neo1 we love perfection

VINCENTpartial_body The passive partial hand system enables prosthetic reconstruction of a partial hand. It consists of functional passive finger and thumb prostheses that can be locked in place in one or two joints in different angular positions. The weight-optimized stainless steel joints with variable-length finger or thumb attachments are very robust and water-resistant. The variable-length finger or thumb sleeves are made of durable and stain-resistant HTV silicone. The fingers are mounted directly to the stem with two screws coming from the stem or are aligned and fixed in position via various frame types made of stainless steel sheet and aluminum adapters. The fingers can be equipped with one or two successive ratchet joints. The joints function in such a way that pulling in the distal finger direction releases the locking of the joint - positioning is now possible. Releasing the finger causes the joint to lock into the desired position. In addition to the distal locking joint, the thumb has a proximal basic joint for lateral pivoting. The basic joint can be pivoted by 110° via friction locking, and the force required for this can be adjusted. The thumb is aligned and fixed in place by means of a frame plate and a threaded base plate, which can also be laminated directly into the stem. All in all, VINCENTpartial passive is an easy-to-use, robust and functional passive finger and thumb system. Flyer VINCENTpartial_body

VINCENT Certification General information about our courses Our myoelectric prostheses can only be purchased by qualified personnel who have previously successfully completed a certification course in our company or online. Without this course , the following product categories can be ordered from us: - VINCENTpartial passiv - VINCENTpower USB flex - VINCENTwork - Accessories A VINCENT certificate is required for fitting our myoelectric hand and partial hand prostheses. We recommend attending the certification course not only for orthopedic technicians, but also for occupational therapists and physiotherapists who are involved in the fitting of patients. In our certification course, you will learn about our different prostheses, our unique control concept and all the adjustment options of the prostheses with the help of our app. Dates & Prices For dates and prices, please call +49 721 480 714 0 or send us an e-mail: sales@vincentsystems.de You are also welcome to send us a register form via the following links: VINCENT hand prostheses (VINCENTcertificate HAND Basic) VINCENT partial hand prostheses (VINCENTcertificate PARTIALHAND4 Basic) The digital courses guide you through all topics of the VINCENT hand prosthesis systems. The course enables you to use all system components. Upon successful completion of the course program, you will receive a certificate that identifies you as a qualified Vincent Systems customer. This gives you access to all services.

Vincent Systems is a young, dynamic, internationally oriented company from Karlsruhe with customers in Europe, Asia and North America. Vincent Systems GmbH was founded in May 2009 by CEO Dr Stefan Schulz.

Close VINCENTmobile App HOME - Prosthesis : all technical information on the prosthesis, battery status, and user statistics with the number of in-use grasps can be found here. - About: all technical information about the app can be found here. SENSORS - Display of the individual sensor signals. - Sensor settings. Up

Close Up VINCENTgame Separate app to learn the controls of the prosthesis by playing.

1998 - Fluidhand 1 This first soft hand consists of thin foil layers, which have been joined together to form more complex drives in a sandwich construction. Five fingers, built up from 6 foil layers each, functionally welded in pairs, with the middle two foils forming the skeletal structure filled with epoxy resin. The outer two foil layers each form a fluidic muscle. For this purpose, two thin films were welded together in such a manner that chambers were formed in a row and connected to each other. When this structure is inflated with a gas or liquid, it contracts by about 20 % of its length, similar to the natural muscle, and the finger curls up like a bow. After a practical semester and his diploma thesis at the Karlsruhe Research Center (now KIT), Stefan Schulz graduated with a degree in electrical engineering and device systems technology from the University of Rostock and took up a position as a research assistant at the Research Center. Already as a student at the University of Rostock, Schulz worked on the development of alternative miniature drives and patented a process for the production of planar fluid drives on a foil basis. At the Research Center, he continued developing this technology, particularly targeting applications in the field of fluidic robotics, so-called soft robotics in the environment of medical technology research topics. The aim of the work was to develop new drives for instruments used in minimally invasive surgery. Schulz's first applications for the new technology were flexible fluid actuators, miniature catheters for diagnostics, endoscope guidance systems for minimally invasive surgery and diagnostic colonoscopy systems. Fluidhand 1 was created as a “by-product” during the development of a camera guidance system for laparoscopy. The same artificial muscles that enable the movement of a laparoscope camera also work in the Fluidhand 1. In this process, two layers of film are welded together in a diamond-like pattern to form a chamber. When a pressure is applied to this chamber, the flexurally limp but stretch-resistant foil layers form circular arcs, resulting in a shortening of the previously flat structure. The artificial muscles formed in this way work as agonist and antagonist in the Fluidhand 1 and enable the artificial finger and thumb to be bent and stretched and stiffened. A single finger can describe a 180 degree arc, but the force of the artificial muscles is very low due to the material and not suitable for holding objects heavier than approx. 100 g. Up

2004 - Fluidhand 7 Up The Fluidhand 7 is designed as an experimental hand. It is used to develop new control methods and to test a new tank system that is capable of storing energy. The hand therefore has one valve for each of the 8 drives. A type of spring accumulator was developed for the hydraulic tank, which allows the hand to be closed quickly and silently without the hydraulic pump operating. Due to the large number of new and experimental components, the metacarpus has turned out to be significantly larger than the previous model, but at this stage of development, the anatomical shape and size of the hand is not a priority. For the hydraulic system, experiments were carried out with a tank that allows energy recovery when the hand is opened. The tank consists of a rigid outer shell and an elastic tank bladder inside. Between the outer shell and the tank bubble is a two-phase gas under constant pressure of 2 bar. In the intermediate space, just enough gas is formed from the liquid aggregate state until a constant pressure is reached. When the hand is opened, gas is formed; when it is closed, it is compressed into liquid, at a constant working pressure of 2 bar at room temperature. The internal diaphragm with the hydraulic fluid is thus under the pressure of the gas. When a valve is opened, a finger joint is already moved without the hydraulic pump having been activated. The pump can then build up even greater grasping force with a time delay. In this way, very dynamic and also noiseless finger movements are possible. When the drives are emptied, the water is pressed back into the tank, against the pressure of the two-phase gas, and the system is ready for the next grasping process. Up

VINCENTaqua - waterproof neoprene sleeve Splash-water protection for the prosthetic socket for forearm fittings: Protects against splash-water, running water and temporary submersion*. The sleeve is made of neoprene with a textile surface and is individually custom-made. Available in black or with printed wave design in blue, green or violet. *When used properly for a max. of 1 hour in max. 1 m deep water. Flyer VINCENTaqua VINCENTaqua we love perfection

MDR (Medical Device Regulation) Declarations of conformity according to MDR Since May 26, 2021, the new EU Medical Device Regulation (MDR) (EU 2017/745) is mandatory for medical device manufacturers. This replaces the Medical Device Directive (MDD) (93/42/EEC) which was valid until then. All declarations of conformity of our medical devices have been updated by the introduction of the MDR, according to its requirements. The declarations of conformity are available to you, as our certified customer, for download in the customer online portal. EUDAMED EUDAMED is the European database for medical devices. It serves the central administration of medical devices in the EU and is based on a resolution of the EU Commission (2010/227/EU) from the year 2010. Through the MDR (Medical Device Regulation (EU 2017/745)), we as manufacturers are obligated to provide informations about us and our products in the database. In EUDAMED we are registered under the following Single Registration Number (SRN): DE-MF-000016437